Filling machine

ABSTRACT

Provided is a multitrack filling machine configured to obtain closed bags from a plurality of packing ribbons, including conveying means for the packing ribbon and a plurality of sacking stations, each including forming means, sealing means, filling means, cutting means, in which each sacking station includes driving means for the packing ribbon separated from the sealing means and including a dragging surface of high friction configured to interact by contact with the ribbon and to drag it along in the advancing direction.

The present invention relates to a filling machine of the type pointed out in the preamble of the first claim.

Presently known are filling machines adapted to produce sealed packages having various contents. In particular, the filling machines form a plurality of bags and sachets in sequence starting from a packing sheet and the loose product.

Most of the filling machines operate as follows.

A packing sheet is placed close to the machine and starting from this sheet wound up into a reel the bags or sachets will be made. The sheet is unrolled and conveyed to a forming and sealing apparatus. Along this apparatus the sheet is wrapped on a tube having a transverse axis relative to the major extension direction of the sheet and a circumference slightly smaller than the sheet width. The advancing sheet portions wrapped along the tube are mutually joined and sealed. It is therefore a seal in the longitudinal direction relative to the major extension direction of the sheet.

Subsequently the longitudinally sealed sheet extends beyond the tube along which it is wrapped and is sealed transversely. The transverse seal is cut in the middle so that the transverse seal acts as head sealing for one bag and bottom sealing for the following bag. In addition, the bag that has received the bottom sealing is filled with the product in such a manner that the product remains inside the bag when the head sealing has been carried out.

During this process unrolling of the sheet is carried out by the transverse sealing device that, while it is grasping the two opposite flaps of the wrapped sheet for mutually sealing them, drives the same in the unrolling direction.

Thanks to these filling machines most of the objects of any size are sacked, from the single-dose condiment-containing sachets of a width less than one centimetre, to the earth-holding bags more than one metre wide. In addition, in order to improve productivity of the filling machines, multitrack filling machines have been produced.

In these machines the sheet wound up on a reel is divided, in the longitudinal direction, into a plurality of sheets or ribbons, each of which is adapted to make a series of bags. Several bags in parallel are therefore produced and the process is greatly speeded up.

The known art mentioned above has some important drawbacks.

In fact, the multitrack filling machines are not adapted to unroll sheets of great overall width, exceeding some tens of centimetres, for example. This drawback is due to the fact that high stresses and friction are created between the sheet and the sheet conveying and driving apparatus so that the tension on the different sheet portions cannot be maintained to a constant level. Thus the multitrack filling machines can only produce sachets of a very reduced width, the so-called “sticks”, and in addition a reduced number of tracks in parallel can be provided.

A further drawback resides in that the sachets that in parallel come out of the multitrack filling machines are in tight contact with each other. Thus particular sealing or forming elements for the bags cannot be placed close to the multitrack filling machines due exactly to the lack of space between the bags. Under this situation the technical task underlying the present invention is to device a multitrack filling machine capable of substantially obviating the mentioned drawbacks.

Within the scope of this technical task, it is an important aim of the invention to obtain a multitrack filling machine capable of operating with sheets of great width and therefore adapted to produce, in parallel, either several bags of great width or a great number of bags of reduced width.

Another important aim of the invention is to make available a multitrack filling machine provided with particular sealing or forming elements for the bags.

The technical task mentioned and the aims specified are achieved by the particular sealing or forming elements for the bags as claimed in the appended independent claims.

Preferred embodiments are highlighted in the sub-claims.

The features and advantages of the invention are hereinafter clarified by the detailed description of a preferred embodiment of the invention, with reference to the accompanying drawings, in which:

FIG. 1 a shows a front view of a four-track filling machine according to the invention;

FIG. 1 b shows a top view of a four-track filling machine according to the invention;

FIG. 2 a is a front view of a six-track filling machine according to the invention;

FIG. 2 b is a top view of a six-track filling machine according to the invention;

FIG. 3 is a top view of a variant of a filling machine according to the invention;

FIG. 4 reproduces a detail of the filling machine according to the invention;

FIG. 5 diagrammatically shows a bag obtained by use of the filling machine according to the invention.

With reference to the drawings, the multitrack filling machine according to the invention is generally identified by reference number 1.

It is adapted to form closed bags 50 from a plurality of packing ribbons or strips 51 suitably formed by longitudinally cutting a single packing sheet 57 wound up on a reel 58.

Each packing ribbon 51 defines a longitudinal direction 52 and a transverse direction 53 perpendicular to said longitudinal direction 52.

In particular, the filling machine 1 is adapted to make closed bags 50 formed with a transverse portion of packing ribbon 51 folded over upon itself in the longitudinal direction 52 in such a manner that two longitudinal flaps 54 of the transverse portion are mutually superposed and sealed and that the lower 55 and upper 56 edges of the bag 50 are mutually sealed, as shown in FIG. 5. The filling machine 1 briefly comprises conveying means 2 and a plurality of sacking stations 3 each including: forming means 4, sealing means 5, filling means 6, cutting means 7 and driving means 8.

In greater detail, the conveying means 2 defines an unrolling trajectory for the packing ribbons 51, in a manner adapted to supply each sacking station 3 with a packing ribbon 51, along an advancing or feeding direction.

Said means comprises a reel-unrolling unit 9, preferably structurally independent of the rest of the machine. It is adapted to move reels 58 having large diameters and widths, diameters even exceeding one meter and widths larger than 1.25 metres, for example. Therefore unit 9 is able to provide a long period of self-government by greatly increasing the time intervening between two reel changes, and consequently the efficiency of the machine itself.

The reel-unrolling unit 9 preferably comprises a reel-carrying axis 9 a actively actuated by a servomotor, operated based on the information of sensors measuring the reel 58 diameter.

Unit 9 further comprises a roller assembly 9 c consisting of a plurality of movable conveying rollers and adapted to accumulate the packing sheet 57 waiting for processing and to adjust tension thereof.

The reel-unrolling unit 9 further comprises longitudinal-cutting knives 9 d adapted to longitudinally divide the packing sheet 57 into a plurality of packing ribbons 51, preferably four or six ribbons 51.

The reel-unrolling unit 9 finally comprises a pair of opposite powered pulling rollers 9 e substantially forming a calender. Said rollers 9 e preferably have a high-friction surface, made of elastomer for example, and are adapted to ensure control in conveying the ribbons 51 downstream of the reel-unrolling unit 9.

The conveying means 2 further comprises a deviation unit 10, downstream of the reel-unrolling unit 9. The deviation unit 10 comprises deviating devices 10 b consisting of rollers or bars oriented at 45° relative to the exit direction of ribbons 51 from the reel-unrolling unit 9 and adapted to deviate ribbons 51 through a right angle. In particular a deviating device 10 b is present for each ribbon 51.

Furthermore, alongside each deviating device 10 b there are rollers 10 a movable along the unrolling trajectory of the deviated ribbon 51, for fine adjustment of the path length of the packing ribbon 51.

The conveying means 2 finally preferably comprises tensioning rollers 11 placed in the vicinity of stations 3. They preferably have an outer surface of high friction, in particular made of elastomer or the like. Furthermore, they are able to detect the tension of ribbon 51, as better specified in the following.

Disposed downstream of the conveying means there are the sacking stations 3 preferably of same number as the number of ribbons 51.

The sacking stations 3 preferably mainly extend in the vertical direction. The longitudinal direction of ribbon 51 in this portion of the machine 1 is therefore suitably coincident with the vertical direction. Each sacking station 3 first of all comprises forming means 4 for the packing ribbon 51. This means is adapted to fold one transverse portion of one of ribbons 51 along the longitudinal direction 52, in such a manner that the two longitudinal flaps 54 of the transverse portion of ribbon 51 are superposed.

The forming means 4 suitably comprises a collar 12 known by itself and consisting of a surface along which ribbon 51 is disposed for running inside a short portion of an underlying tube.

Collar 12 is followed by a forming tube 13 around which ribbon 51 is disposed, fully wrapping it in the circumferential direction, leaving the two longitudinal flaps 54 unwrapped around the circumference and mutually opposite.

Disposed downstream of the forming means 4 is the sealing means 5. This means comprises a longitudinal sealing device 14 adapted to seal the two superposed longitudinal flaps 54. This device 14 suitably carries out sealing by heat. In particular it comprises a heated portion adapted to be moved by suitable movement means, so as to come into contact with the two flaps 54. It is suitably provided with temperature control and pneumatic movement means, independent for each individual station 3. It can further comprise pulse sealing means, i.e. through electric heating.

The sealing means 5 also comprises a transverse sealing device 15 adapted to seal the ribbon 51 in the transverse direction 53 at given longitudinal space intervals. This device 15 too suitably carries out sealing by heat supply. In particular it comprises a series of opposite bars, heated preferably by independent heating, disposed after the forming tube 13 and adapted to be moved by suitable movement means, so as to come into contact with the two longitudinally-sealed opposite portions. It is suitably disposed on a single support for all stations 3. It can further comprise pulse sealing means, i.e. through electric heating.

Also disposed at the transverse sealing device 15 can be a bag shaping device 50 consisting of a known device for making a square bottom or the like, for example.

Stations 3 then comprise filling means 6 (FIG. 1 a), which means is adapted to fill an open bag with the intended products, i.e. a bag that has been submitted to the longitudinal and transverse seals, the latter constituting the bag bottom, and has the upper portion open. The filling means 6 is known by itself and introduces the products through collar 12 and the forming tube 13.

Stations 3 also comprise cutting means 7 downstream of the sealing means 5 of ribbon 51. This means preferably consists of two opposite cutters and divides the bags 50 at the sealing in the transverse direction so that said sealing in the transverse direction constitutes the lower edge 55 of the open bag to be then filled and the upper edge 56 of the bag 50 made in the preceding space interval of ribbon 51.

Finally, each sacking station 3 advantageously comprises driving means 8 for ribbon 51. This driving means 8 is separated from the sealing means 5 and comprises a dragging surface 16 of high friction, preferably made of elastomer or the like, adapted to interact by contact with ribbon 51 and to drag the latter along in the feeding direction.

In particular the driving means 8 is disposed between the forming means 4 and cutting means 7. In more detail, this means is preferably disposed at the forming tube 13, in such a manner that the dragging surface 16 comes into contact with the ribbon 51 in turn wrapped on tube 13. The driving means 8 is shown in FIG. 4 and preferably consists of crawler tracks 17 driven by wheels 18. The outer surface of the tracks constitutes therefore the dragging surface 16. Tracks 17 preferably have a surface layer of elastomer and more particularly of natural rubber, and a toothed inner layer of stiffer and stronger material.

Tracks 17 preferably have width included between 1 cm and 3 cm and are wrapped around an angular portion of the forming tube 13 included between 20° and 3020 ; their thickness is included between 2 mm and 1 cm and the length is included between 30 cm and 80 cm.

The driving means 8 of each individual station 3, according to an innovative process, can be further suitably adjusted in an independent manner as a function of the tension of the individual ribbon 51, and each track 17 is preferably set in motion by a single servomotor.

The machine 1 further comprises tension sensors 19 for the individual ribbons 51, adapted to check the tension of said individual ribbons 51. They can be disposed at the tensioning rollers 11 for example and consist of sensors adapted to check the vertical displacements of said rollers 11. Alternatively, they can consist of optical reading means or other means known by itself.

Operation of a multitrack filling machine 1 described above as to its structure is the following.

The machine 1 preferably moves ribbon 51 with alternate pauses. First of all, the reel-unrolling unit 9 unrolls a portion of reel 58 and feeds the roller assembly 9 c, in turn feeding the remaining portion of the machine 1. Activation of the roller assembly 9 c takes place through unrolling of reel 58 by a servomotor moving axis 9 c, taking into account the information both from sensors placed on the roller assembly 9 c and from a sensor measuring the diameter of reel 58.

The packing sheet 57 is then unrolled, separated into ribbons by knives 9 d and conveyed to the pulling rollers 9 e. Each ribbon corresponds therefore to a track comprising a station 3.

From the pulling rollers 9 e onwards, unrolling of ribbons 51 is suitably timed with the operations of stations 3. In particular, in a movement step, ribbons 51 are moved towards stations 3. In detail, the driving means 8 is simultaneously activated on all tracks 3, each crawler track 17 receiving motion from a single servomotor. Simultaneously, the pulling rollers 9 e are suitably activated by a servomotor. In particular, the pulling rollers 9 e and driving means 8 are connected in an electric axis so that ribbons 51 are simultaneously dragged along by the roller assembly 9 c.

In the portion between the driving means 8 and pulling rollers 9 e, the individual ribbons 51 are dragged along, being compensated in position by rollers 10 a and deviated by the deviating devices 10 b; subsequently they pass through the tensioning rollers 11 and reach stations 3. In particular, deviation of ribbons 51 enables stations 3 to be disposed at arbitrary mutual distances. Therefore said stations enable the aforesaid shaping device or driving 8 and sealing devices 15 with said “square bottom” to be introduced.

Consequently, each ribbon 51 enters its own station 3. At each station 3 each ribbon 51 passes through the forming means 4 and takes the shape required for the subsequent sealing step through the sealing 5 and cutting 7 means. In addition, in the portion in question, tension of the packing material is controlled by adjusting the speed ratio between the driving means 8 and the pulling rollers 9 e.

When the movement step has been completed a pause step begins. Ribbons 51 are therefore stationary, the longitudinal sealing devices 14 are operated by a pneumatic movement for coming into contact with ribbons 51 and carrying out the longitudinal seal.

Simultaneously, the transverse sealing device 15 is operated by a servomotor for coming into contact with the packing ribbon 51 and carrying out the transverse sealing.

Still simultaneously, the cutting means 7 is driven by the servomotor and carries out the simultaneous cut lengthwise in all stations 3. Suitably, in this step also the measuring process for the product to be packaged by the filling means 6 takes place.

The invention comprises a new process for material sacking or for operating multitrack filling machines 1. The process contemplates the above disclosed operation.

The invention enables important advantages to be achieved.

In fact the machine, due to the presence of the particular driving means 8 is able to use and work also sheets of important width, exceeding 1.25 m for example, with great ability.

Consequently this machine 1 can make closed bags 50 that are very large or a great number of bags 50 in parallel, therefore greatly improving productivity, as productivity in the examples shown is four and six times higher than in known machines.

The quality of bags 50 obtained in the individual stations 3 is ensured by the tension control that is independent in each track.

In addition, since the ribbons are deviated, according to the two configurations shown (FIG. 1 b and FIG. 3), stations 3 can be spaced apart and bulky elements can be introduced, as previously said.

The invention is susceptible of variations falling within the inventive idea defined by the independent claims. All of the details can be replaced by equivalent elements and the materials, shapes and sizes can be of any nature and magnitude. 

1. A multitrack filling machine configured to obtain closed bags from a plurality of packing ribbons, each of said packing ribbons defining a longitudinal direction and a direction perpendicular to said longitudinal direction, said packing machine comprising a plurality of sacking stations, each comprising forming means for said packing ribbon configured to fold a tranverse portion of one of said packing ribbons along a longitudinal direction, in a manner adapted to superpose two longitudinal flaps of said transverse portion of said packing ribbon, sealing means configured to seal said two superposed longitudinal flaps and seal said packing ribbon in the transverse direction, at given space intervals, filling means to fill an open bag formed with said packing ribbon longitudinally and transversely sealed, in such a manner that said transverse seal constitutes the bottom of said open bag, cutting means to cut said packing ribbon at said seal in the transverse direction, in such a manner that said seal in the transverse direction constitutes the bottom of said open bag and the head closure of the one closed bag obtained in the previous space interval of packing ribbon, said filling machine comprising conveying means for said plurality of packing ribbons configured to convey said packing ribbons along an unrolling trajectory and an advancing or feeding direction in a manner configured to supply each of said sacking stations with one of said packing ribbons, wherein each of said sacking stations comprises driving means for said packing ribbon separated from said sealing means and comprising a high-friction dragging surface configured to interact by contact with said packing ribbon and drive it in the advancing direction.
 2. The machine as claimed in claim 1, wherein said driving means comprises crawler tracks defining said dragging surface.
 3. The machine as claimed in claim 2, wherein said driving means comprises opposite crawler tracks.
 4. The machine as claimed in claim 1, wherein said forming device comprises a forming tube and is adapted configured to wrap said packing ribbon around said forming tube, and wherein said dragging surfaces are provided at said forming tube.
 5. The machine as claimed in claim 1, wherein said dragging surface is made of elastomer.
 6. The machine as claimed in claim 1, wherein said driving means of said different sacking stations is independently adjustable.
 7. The machine as claimed in claim 1, comprising tension sensors for the individual ribbons, configured to measure the tension of said individual ribbons.
 8. The machine as claimed in claim 1, wherein said conveying means comprises a deviation unit configured to deviate said packing ribbons through a right angle.
 9. The machine as claimed in claim 1, wherein said conveying means comprises pulling rollers upstream of said sacking stations, in timed relationship with said driving means and configured to drag said packing ribbons along.
 10. The machine as claimed in claim 1, further comprising tensioning rollers placed in the vicinity of said sacking stations and provided with an outer surface of high friction. 